المؤلفون: Braun, Edward L, Kimball, Rebecca T, Han, Kin-Lan, Iuhasz-Velez, Naomi R, Bonilla, Amber J, Chojnowski, Jena L, Smith, Jordan V, Bowie, Rauri CK, Braun, Michael J, Hackett, Shannon J, Harshman, John, Huddleston, Christopher J, Marks, Ben D, Miglia, Kathleen J, Moore, William S, Reddy, Sushma, Sheldon, Frederick H, Witt, Christopher C, Yuri, Tamaki

المصدر: BMC Evolutionary Biology. 11(1)

الوصف: Abstract Background Microinversions are cytologically undetectable inversions of DNA sequences that accumulate slowly in genomes. Like many other rare genomic changes (RGCs), microinversions are thought to be virtually homoplasy-free evolutionary characters, suggesting that they may be very useful for difficult phylogenetic problems such as the avian tree of life. However, few detailed surveys of these genomic rearrangements have been conducted, making it difficult to assess this hypothesis or understand the impact of microinversions upon genome evolution. Results We surveyed non-coding sequence data from a recent avian phylogenetic study and found substantially more microinversions than expected based upon prior information about vertebrate inversion rates, although this is likely due to underestimation of these rates in previous studies. Most microinversions were lineage-specific or united well-accepted groups. However, some homoplastic microinversions were evident among the informative characters. Hemiplasy, which reflects differences between gene trees and the species tree, did not explain the observed homoplasy. Two specific loci were microinversion hotspots, with high numbers of inversions that included both the homoplastic as well as some overlapping microinversions. Neither stem-loop structures nor detectable sequence motifs were associated with microinversions in the hotspots. Conclusions Microinversions can provide valuable phylogenetic information, although power analysis indicates that large amounts of sequence data will be necessary to identify enough inversions (and similar RGCs) to resolve short branches in the tree of life. Moreover, microinversions are not perfect characters and should be interpreted with caution, just as with any other character type. Independent of their use for phylogenetic analyses, microinversions are important because they have the potential to complicate alignment of non-coding sequences. Despite their low rate of accumulation, they have clearly contributed to genome evolution, suggesting that active identification of microinversions will prove useful in future phylogenomic studies.

وصف الملف: application/pdf

الوصول الحر: https://escholarship.org/uc/item/6w79434fTest

المؤلفون: Marks Ben D, Huddleston Christopher J, Harshman John, Hackett Shannon J, Braun Michael J, Smith Jordan V, Bowie Rauri CK, Chojnowski Jena L, Bonilla Amber J, Iuhasz-Velez Naomi R, Han Kin-Lan, Kimball Rebecca T, Braun Edward L, Miglia Kathleen J, Moore William S, Reddy Sushma, Sheldon Frederick H, Witt Christopher C, Yuri Tamaki

المصدر: BMC Evolutionary Biology, Vol 11, Iss 1, p 141 (2011)

مصطلحات موضوعية: Evolution, QH359-425

الوصف: Abstract Background Microinversions are cytologically undetectable inversions of DNA sequences that accumulate slowly in genomes. Like many other rare genomic changes (RGCs), microinversions are thought to be virtually homoplasy-free evolutionary characters, suggesting that they may be very useful for difficult phylogenetic problems such as the avian tree of life. However, few detailed surveys of these genomic rearrangements have been conducted, making it difficult to assess this hypothesis or understand the impact of microinversions upon genome evolution. Results We surveyed non-coding sequence data from a recent avian phylogenetic study and found substantially more microinversions than expected based upon prior information about vertebrate inversion rates, although this is likely due to underestimation of these rates in previous studies. Most microinversions were lineage-specific or united well-accepted groups. However, some homoplastic microinversions were evident among the informative characters. Hemiplasy, which reflects differences between gene trees and the species tree, did not explain the observed homoplasy. Two specific loci were microinversion hotspots, with high numbers of inversions that included both the homoplastic as well as some overlapping microinversions. Neither stem-loop structures nor detectable sequence motifs were associated with microinversions in the hotspots. Conclusions Microinversions can provide valuable phylogenetic information, although power analysis indicates that large amounts of sequence data will be necessary to identify enough inversions (and similar RGCs) to resolve short branches in the tree of life. Moreover, microinversions are not perfect characters and should be interpreted with caution, just as with any other character type. Independent of their use for phylogenetic analyses, microinversions are important because they have the potential to complicate alignment of non-coding sequences. Despite their low rate of accumulation, they have clearly contributed to genome evolution, suggesting that active identification of microinversions will prove useful in future phylogenomic studies.

وصف الملف: electronic resource

العلاقة: http://www.biomedcentral.com/1471-2148/11/141Test; https://doaj.org/toc/1471-2148Test

الوصول الحر: https://doaj.org/article/1deda5f968d8425a9ed554f5b6e15c96Test

المؤلفون: Hannah L Curtis, Braun Edward L, Georgelis Nikolaos

المصدر: BMC Evolutionary Biology, Vol 8, Iss 1, p 232 (2008)

مصطلحات موضوعية: Evolution, QH359-425

الوصف: Abstract Background ADP-glucose pyrophosphorylase (AGPase), which catalyses a rate limiting step in starch synthesis, is a heterotetramer comprised of two identical large and two identical small subunits in plants. Although the large and small subunits are equally sensitive to activity-altering amino acid changes when expressed in a bacterial system, the overall rate of non-synonymous evolution is ~2.7-fold greater for the large subunit than for the small subunit. Herein, we examine the basis for their different rates of evolution, the number of duplications in both large and small subunit genes and document changes in the patterns of AGPase evolution over time. Results We found that the first duplication in the AGPase large subunit family occurred early in the history of land plants, while the earliest small subunit duplication occurred after the divergence of monocots and eudicots. The large subunit also had a larger number of gene duplications than did the small subunit. The ancient duplications in the large subunit family raise concern about the saturation of synonymous substitutions, but estimates of the absolute rate of AGPase evolution were highly correlated with estimates of ω (the non-synonymous to synonymous rate ratio). Both subunits showed evidence for positive selection and relaxation of purifying selection after duplication, but these phenomena could not explain the different evolutionary rates of the two subunits. Instead, evolutionary constraints appear to be permanently relaxed for the large subunit relative to the small subunit. Both subunits exhibit branch-specific patterns of rate variation among sites. Conclusion These analyses indicate that the higher evolutionary rate of the plant AGPase large subunit reflects permanent relaxation of constraints relative to the small subunit and they show that the large subunit genes have undergone more gene duplications than small subunit genes. Candidate sites potentially responsible for functional divergence within each of the AGPase subunits were investigated by examining branch-specific patterns of rate variation. We discuss the phenotypes of mutants that alter some candidate sites and strategies for examining candidate sites of presently unknown function.

وصف الملف: electronic resource

العلاقة: http://www.biomedcentral.com/1471-2148/8/232Test; https://doaj.org/toc/1471-2148Test

الوصول الحر: https://doaj.org/article/5f6ddfb437d847cfbcd137834dd2a311Test

المؤلفون: Georgelis, Nikolaos¹ gnick@ufl.edu, Braun, Edward L.² ebraun68@ufl.edu, Hannah, L. Curtis¹ hannah@mail.ifas.ufl.edu

المصدر: BMC Evolutionary Biology. 2008, Vol. 8, Special section p1-17. 17p. 3 Diagrams, 2 Charts, 1 Graph.

مصطلحات موضوعية: *ADENOSINE diphosphate, *PHOSPHORYLASES, *PLANT genetics, *GLUCOSE synthesis, *AMINO acids, *PLANT chromosome numbers, *BIOLOGICAL evolution, *GENETICS

مستخلص: Background: ADP-glucose pyrophosphorylase (AGPase), which catalyses a rate limiting step in starch synthesis, is a heterotetramer comprised of two identical large and two identical small subunits in plants. Although the large and small subunits are equally sensitive to activity-altering amino acid changes when expressed in a bacterial system, the overall rate of non-synonymous evolution is ∼2.7-fold greater for the large subunit than for the small subunit. Herein, we examine the basis for their different rates of evolution, the number of duplications in both large and small subunit genes and document changes in the patterns of AGPase evolution over time. Results: We found that the first duplication in the AGPase large subunit family occurred early in the history of land plants, while the earliest small subunit duplication occurred after the divergence of monocots and eudicots. The large subunit also had a larger number of gene duplications than did the small subunit. The ancient duplications in the large subunit family raise concern about the saturation of synonymous substitutions, but estimates of the absolute rate of AGPase evolution were highly correlated with estimates of ω (the non-synonymous to synonymous rate ratio). Both subunits showed evidence for positive selection and relaxation of purifying selection after duplication, but these phenomena could not explain the different evolutionary rates of the two subunits. Instead, evolutionary constraints appear to be permanently relaxed for the large subunit relative to the small subunit. Both subunits exhibit branch-specific patterns of rate variation among sites. Conclusion: These analyses indicate that the higher evolutionary rate of the plant AGPase large subunit reflects permanent relaxation of constraints relative to the small subunit and they show that the large subunit genes have undergone more gene duplications than small subunit genes. Candidate sites potentially responsible for functional divergence within each of the AGPase subunits were investigated by examining branch-specific patterns of rate variation. We discuss the phenotypes of mutants that alter some candidate sites and strategies for examining candidate sites of presently unknown function. [ABSTRACT FROM AUTHOR]